WO1999018642A1 - Surge arrester having single surge arresting block - Google Patents

Abstract

A surge arrester includes an electrically insulating arrester housing and a surge arresting block housed within the electrically insulating arrester housing. The surge arresting block is arranged to provide support for the surge arrester without the use of a support member. The surge arresting block may be a single surge arresting block having a voltage rating of at least 9 KV. The surge arresting block may have threads formed integrally therewith.

Description

SURGE ARRESTER HAVING SINGLE SURGE ARRESTING BLOCK

Technical Field of the Invention

The present invention relates to a surge ar¬

rester for shunting electrical surges to ground.

Background of the Invention

Overvoltage surges, which travel along an elec¬

tric power distribution system and which are not properly

averted or diverted, often damage transformers and other

electrical equipment of the electric power distribution

system, as well as the electrical equipment of residen¬

tial, commercial and industrial customers supplied by the

electric power distribution system. Consequently, surge

arresters are commonly used in an electric power distri¬

bution system for shunting overvoltage surges to system

ground before the overvoltage surges can damage the elec¬

trical equipment connected in, or to, the electric power

distribution system. A typical surge arrester used in electric power

distribution systems comprises an insulating housing, a

stack of surge arresting blocks, end connectors which are

in electrical contact with each end of the surge arrest-

ing blocks and which are arranged to electrically connect

the surge arrester between first and second electrical

lines, and a fault disconnector for disconnecting the

surge arrester from the first and/or second electrical

lines in the event of a fault in the surge arresting

block. The number of surge arresting blocks in the stack

of surge arresting blocks depends on the geometry of the

surge arresting blocks and the voltage rating of the

surge arrester. For example, a surge arrester rated at 9

KV usually has two or three surge arresting blocks.

The insulating housing of the typical non-

porcelain surge arrester is not strong enough to support

and contain the stack of surge arresting blocks. There¬

fore, a support member, such as a fiberglass wrap or a

fiberglass sleeve, is provided around the stack of surge

arresting blocks and the end connectors in order to con¬

tain and support the surge arresting blocks within the insulating housing. Additional elements, such as spring-

s, wave washers, and/or the like, are provided in order

to compress the surge arresting blocks.

Because of the use of a support member and

multiple surge arresting blocks, a surge arrester as

described above is expensive to produce. The present

invention is directed to a surge arrester which elimi¬

nates the need for a support member and/or which uses a

reduced number of surge arresting blocks.

Summary of the Invention

In accordance with one aspect of the present

invention, a surge arrester comprises an electrically

insulating arrester housing and a surge arresting block

housed within the electrically insulating arrester hous-

ing. The surge arresting block is arranged to provide

support for the surge arrester without the use of a sup¬

port member.

In accordance with another aspect of the pres¬

ent invention, a surge arrester comprises a single surge

arresting block housed within an electrically insulating arrester housing. The single surge arresting block is

fabricated of a material, and the single surge arresting

block has threads formed of the material .

In accordance with yet another aspect of the

present invention, a surge arrester comprises a surge ar¬

resting block housed within an electrically insulating

arrester housing. The surge arresting block is fabri¬

cated of a continuous material so that the surge arrest¬

ing block is of unitary construction, and the surge ar-

resting block has a voltage rating of at least 9 KV.

In accordance with still another aspect of the

present invention, a method of forming a surge arresting

block comprises the following steps: a) placing suffi¬

cient material in an isostatic press to form a surge

arresting block having a voltage rating of at least 9 KV;

and b) controlling the isostatic press with a pres¬

sure/time profile arranged to bond the material together

in order to form the surge arresting block.

Brief Description of the Drawings These and other features and advantages of the

present invention will become more apparent from a de¬

tailed consideration of the invention when taken in con¬

junction with the drawings in which:

Figure 1 illustrates a surge arrester which

incorporates a surge arresting block and a pair of end

connectors and which is arranged in accordance with the

present invention;

Figure 2 illustrates a subassembly of the surge

arrester shown in Figure 1;

Figure 3 illustrates the surge arresting block

of Figure 1 ;

Figure 4 illustrates the surge arresting block

and end connectors of Figure 1;

Figure 5 illustrates the surge arresting block

and end connectors of Figure 1, wherein the end connec¬

tors are held to the surge arresting block by an electri¬

cally insulating member;

Figure 6 illustrates the surge arresting block

of Figure 1 having female threads in accordance with one

embodiment of the present invention; Figure 7 illustrates the surge arresting block

of Figure 1 having male threads in accordance with an¬

other embodiment of the present invention;

Figure 8 illustrates the surge arresting block

of Figure 1 having male threads in accordance with still

another embodiment of the present invention;

Figure 9 illustrates a plurality of threadably

engaged surge arresting blocks according to a first plu¬

ral block embodiment of the present invention;

Figure 10 illustrates a plurality of threadably

engaged surge arresting blocks according to a second

plural block embodiment of the present invention;

Figure 11 illustrates a plurality of threadably

engaged surge arresting blocks according to a third plu-

ral block embodiment of the present invention; and,

Figure 12 illustrates an isostatic press useful

in forming the surge arresting block of the present in¬

vention.

Detailed Description As shown in Figure 1, a surge arrester 10 in¬

cludes a first terminal end 12 and a second terminal end

14. The first terminal end 12 includes a first terminal

16 which is used to electrically connect the surge ar-

rester 10 to a first electrical line. The second termi¬

nal end 14 includes a second terminal 18 which is used to

electrically connect the surge arrester 10 to a second

electrical line. The first electrical line may be, for

example, an electrically conducting lead which connects

the first terminal 16 to a high voltage line of an elec¬

trical power distribution system, and the second elec¬

trical line may be an electrically conducting lead which

connects the second terminal 18 to ground. Alterna¬

tively, however, the first electrical line may be, for

example, an electrically conducting lead which connects

the first terminal 16 to ground, and the second electri¬

cal line may be an electrically conducting lead which

connects the second terminal 18 to a high voltage line of

an electrical power distribution system.

The first terminal 16 is threaded into a first

end connector 20, and the second terminal 18 is electrically connected into a second end connector 22 in

a manner to be described below. The first and second end

connectors 20 and 22 are electrically conductive and, for

example, may be formed from aluminum. A surge arresting

block 24 is in electrical contact with the first and

second end connectors 20 and 22. Accordingly, a series

circuit is formed between the first and second end con¬

nectors 20 and 22. The surge arresting block 24 may be a

metal oxide varistor block, for example, which conducts

in the presence of surges in order to shunt the surge

energy in the electric power distribution system between

the first and second terminals 16 and 18.

An arrester housing 26 houses the first and

second end connectors 20 and 22 and the surge arresting

block 24. As is known, the arrester housing 26 may be an

insulating polymeric or porcelain housing having a plu¬

rality of polymeric or porcelain water sheds 28. A

mounting bracket 30 is provided in order to mount and

support the surge arrester 10 to a utility pole or other

apparatus of an electric power distribution system. As shown in Figures 1 and 2 , the second end

connector 22 has a first end 32 which is in electrical

contact with the surge arresting block 24. The second

end connector 22 also has a second end 34 which comprises

a wall 36 forming a recess 38. A fault disconnector 40

includes a cartridge 42 which is contained within an end

44 of the second terminal 18. The fault disconnector 40

includes a first electrically conductive washer 46 abut¬

ting the end 44 of the second terminal 18, a second elec-

trically conductive washer 50 abutting an internal wall

52 of the second end connector 22, and a resistor 54

sandwiched between the first and second electrically

conductive washers 46 and 50. A plastic cup 56 contains

the first and second electrically conductive washers 46

and 50 and the resistor 54 when the fault disconnector 40

is assembled as shown in Figure 1. Thus, the plastic cup

56 insulates the resistor 54 and the first and second

electrically conductive washers 46 and 50 from the wall

36 of the second end connector 22 to thus direct fault

current to flow from the second end connector 22 through

the second electrically conductive washer 50, through the resistor 54, through the first electrically conductive

washer 46, and through the second terminal 18.

The surge arresting block 24 is shown in Figure

3. The surge arresting block 24 is provided with first

and second metallized electrodes 60 and 62. The first

metallized electrode 60 electrically contacts the first

end connector 20, and the second metallized electrode 62

electrically contacts the second end connector 22. The

first and second metallized electrodes 60 and 62 may be

formed of any electrically conductive material such as

copper, aluminum, zinc, silver, gold, or the like, or of

any suitable electrically conductive composition such as

compositions composed of silver, gold, platinum, palla¬

dium, and/or the like.

The first and second metallized electrodes 60

and 62 may be applied to the surge arresting block 24

dependent upon the electrode forming material . For exam¬

ple, if the first and second metallized electrodes 60 and

62 are formed of silver, the surge arresting block 24 is

fired after it is formed, an electrically insulating

collar is applied to the surge arresting block 24, the first and second metallized electrodes 60 and 62 are then

applied to the surge arresting block 24, and then the

surge arresting block 24 is again fired. The first and

second metallized electrodes 60 and 62 may be applied by

spraying or coating the ends of the surge arresting block

24 with silver. If threads are formed in the ends of the

surge arresting block 24, as discussed below, the ends of

the surge arresting block 24, including the threads, may

be sprayed or coated with silver in order to form the

first and second metallized electrodes 60 and 62.

On the other hand, if the first and second

metallized electrodes 60 and 62 are formed of aluminum,

the surge arresting block 24 is fired after it is formed,

an electrically insulating collar is applied to the surge

arresting block 24, the surge arresting block 24 is then

again fired, and finally the first and second metallized

electrodes 60 and 62 are applied to the surge arresting

block 24. The first and second metallized electrodes 60

and 62 may be applied by arc spraying the ends of the

surge arresting block 24 with aluminum. If threads are

formed in the ends of the surge arresting block 24, the ends of the surge arresting block 24, including the

threads, may be arc sprayed with aluminum in order to

form the first and second metallized electrodes 60 and

62.

After the first and second metallized elec¬

trodes 60 and 62 are applied to the surge arresting block

24, the first and second end connectors 20 and 22 are

suitably attached to the first and second metallized

electrodes 60 and 62, respectively, as shown in Figure 4.

For example, the first and second end connectors 20 and

22 may be bonded to the first and second metallized elec¬

trodes 60 and 62, respectively, by a suitable bonding

agent, such as an electrically conductive epoxy or sol¬

der.

Alternatively, if the first and second end

connectors 20 and 22 are not bonded to the first and

second metallized electrodes 60 and 62, the first and

second end connectors 20 and 22 may be retained on the

surge arresting block 24 by encasing the surge arresting

block 24 and the first and second end connectors 20 and

22 in an electrically insulating material 63 as shown in Figure 5. The first and second end connectors 20 and 22

and the electrically insulating material 63 may be ap¬

plied after the last firing step. The electrically-

insulating material 63, for example, may be fiberglass or

other suitable material, such as epoxy, that can be ap¬

plied as a wrap or sprayed around the first and second

end connectors 20 and 22 and the surge arresting block

24. In this case, the electrically insulating material

63 acts as a support member.

As a further alternative, threads formed in the

surge arresting block 24, as described below, may

threadably engage corresponding threads of the first and

second end connectors 20 and 22 in order to secure the

surge arresting block 24 and the first and second end

connectors 20 and 22 together.

As shown in Figures 1 and 2, the wall 36 of the

second end connector 22 has a circumferential groove 63

therearound. During assembly of the surge arrester 10,

the arrester housing 26 is applied to the subassembly

comprising the surge arresting block 24, the first and

second metallized electrodes 60 and 62, and the first and second end connectors 20 and 22 as shown in Figure 1.

For example, this subassembly may be inserted into the

arrester housing 26. Alternatively, the arrester housing

26 may be molded directly onto this subassembly.

The arrester housing 26 is mounted to the

mounting bracket 30 by inserting the wall 36 through a

hole in the mounting bracket 30 as shown in Figure 1.

The mounting bracket 30 may have a first recess 64 and a

second recess 66 which are concentric with respect to one

another. The second recess 66 is defined by a generally

cylindrical wall 68 of the mounting bracket 30. The

generally cylindrical wall 68 may have an internal taper.

As the second end connector 22 is pushed through the hole

in the mounting bracket 30, a flange 70 of the second end

connector 22 enters the first recess 64 of the mounting

bracket 30, and the taper of the generally cylindrical

wall 68 causes an end portion 72 of the arrester housing

26 to be squeezed between the generally cylindrical wall

68 and the flange 70 of the second end connector 22. As

a result of this squeezing action, the end portion 72

acts as a gasket or seal at the second terminal end 14 in order to isolate the interior of the arrester housing 26

from the external environment . When the arrester housing

26 is fully pressed into the hole of the mounting bracket

30 so that the circumferential groove 63 is accessible, a

snap ring (not shown) is snapped into the circumferential

groove 63 in the wall 36 of the second end connector 22

to thereby clamp the surge arrester 10 to the mounting

bracket 30 with enough force to maintain the seal formed

by the end portion 72 between the generally cylindrical

wall 68 and the flange 70 of the second end connector 22.

A subassembly 74 (Figure 2) is formed by

inserting the second terminal 18, with the cartridge 42

inserted in the end 44, through the plastic cup 56 until

the plastic cup 56 abuts a flange 76 (Figure 1) of the

end 44 of the second terminal 18, and by inserting the

first electrically conductive washer 46 into the plastic

cup 56 until the first electrically conductive washer 46

abuts the flange 76 of the end 44 of the second terminal

18. The resistor 54 is inserted into the plastic cup 56

until the resistor 54 abuts the first electrically con¬

ductive washer 46, and the second electrically conductive washer 50 is placed on top of the resistor 54. The

subassembly 74 is then inserted into the recess 38 of the

second end connector 22 until the second electrically

conductive washer 50 abuts the internal wall 52, leaving

a space 78 as shown in Figure 1. The space 78 is filled

with an epoxy potting material in order to hold the

subassembly 74 in electrical contact with the second end

connector 22.

Instead of using a snap ring in the circum-

ferential groove 63 of the second end connector 22 to

clamp the first and second end connectors 20 and 22, the

surge arresting block 24, and the arrester housing 26 to

the mounting bracket 30, the second end connector 22 may

be threaded into the mounting bracket 30.

As shown in Figure 1, the arrester housing 26

is formed over the first end connector 20 so as to pro¬

vide a seal in cooperation with a flange 90 of the first

terminal 16. This seal at the first terminal end 12

isolates the interior of the arrester housing 26 from the

external environment. Alternatively, the arrester hous¬

ing 26 may be configured with an integral O-ring (not shown) . The integral O-ring may be fitted into an annu¬

lar groove (not shown) formed about the first end connec¬

tor 20 in order to provide a seal at the first terminal

end 12 that isolates the interior of the arrester housing

26 from the external environment.

During formation of the surge arresting block

24, the surge arresting block 24 may be provided with

female threads 100 in an end thereof as shown in Figure

6. Indeed, the surge arresting block 24 may be provided

with female threads 100 at each of its ends. Alterna¬

tively, the surge arresting block 24 may be provided with

male threads 102 in an end thereof, as shown in Figure 7,

during formation of the surge arresting block 24. As in

the case of the female threads 100, the surge arresting

block 24 may be provided with male threads 102 at each of

its ends. As a further alternative, the surge arresting

block 24 may be provided with male threads 104 as shown

in Figure 8.

The female threads 100, the male threads 102,

or the male threads 104 may be arranged to receive

corresponding threads of the first and second end connec- tors 20 and 22. Accordingly, instead of bonding the

first and second end connectors 20 and 22 to the surge

arresting block 24, or instead of retaining the first and

second end connectors 20 and 22 on the surge arresting

block 24 with the electrically insulating material 63, as

discussed above, the first and second end connectors 20

and 22 may be retained on the surge arresting block 24 by

threaded engagement .

Additionally and/or alternatively, the surge

arresting block 24 may be provided with male threads at

one of its ends and female threads at the other of its

ends so that several surge arresting blocks 24 may be

threadably stacked as shown in Figure 9. As shown in

Figure 9, male threads 102b of a surge arresting block

24b are threaded into female threads 100a of a surge

arresting block 24a, and male threads 102c of a surge

arresting block 24c are threaded into female threads 100b

of the surge arresting block 24b. All surge arresting

blocks 24 of this type may have the same voltage rating

so that as many surge arresting blocks 24 as necessary

are stacked as shown in Figure 9 to meet a desired over- all voltage rating. Alternatively, the surge arresting

blocks 24 of this type may have a variety of voltage

ratings so that the surge arresting blocks 24 may be

mixed and matched to meet a desired overall voltage rat-

ing.

As a further additional and/or alternative

embodiment of the present invention, the surge arrescing

block 24 may be provided with female threads at both of

its ends so that several surge arresting blocks 24 may be

threadably stacked as shown in Figure 10. As shown in

Figure 10, a threaded conductive stud 106 (which may be

formed from aluminum, for example) is threaded into fe¬

male threads 108d of a surge arresting block 24d and into

female threads 108e of a surge arresting block 24e so

that the surge arresting blocks 24d and 24e electrically

contact one another. All surge arresting blocks 24 of

this type may have the same voltage rating so that as

many surge arresting blocks 24 as necessary are stacked

as shown in Figure 10 to meet a desired overall voltage

rating. Alternatively, the surge arresting blocks 24 of

this type may have a variety of voltage ratings so that the surge arresting blocks 24 may be mixed and matched to

meet a desired overall voltage rating.

As a still further additional and/or alterna¬

tive embodiment of the present invention, the surge ar-

resting block 24 of the type shown in Figure 8 may be

joined together as shown in Figure 11. As shown in Fig¬

ure 11, a threaded sleeve 109 (which may be formed from a

metal or insulating material, for example) is threaded

onto male threads 104f of a surge arresting block 24f and

onto male threads 104g of a surge arresting block 24g so

that the surge arresting blocks 24f and 24g electrically

contact one another. Element 109a represents metallized

ends of the surge arresting blocks 24f and 24g. All

surge arresting blocks 24 of this type may have the same

voltage rating so that as many surge arresting blocks 24

as necessary are stacked as shown in Figure 11 to meet a

desired overall voltage rating. Alternatively, the surge

arresting blocks 24 of this type may have a variety of

voltage ratings so that the surge arresting blocks 24 may

be mixed and matched to meet a desired overall voltage

rating. A surge arresting block having female threads

100 as shown in Figure 6 may be formed using an isostatic

press 110 as shown in Figure 12. The isostatic press 110

is well known in the art. The isostatic press 110 has

end plugs 112 and 114 which have corresponding recesses

116 and 118. The recesses 116 and 118 receive corre¬

sponding inserts 120 and 122. The insert 120 has a stem

124 that is inserted into the recess 116 of the end plug

112. The insert 120 also has a threaded end 126 that

protrudes into a chamber 128 of the isostatic press 110

when the end plug 112 is applied as shown in Figure 12.

Similarly, the insert 122 has a stem 130 that is inserted

into the recess 118 of the end plug 114. The insert 122

also has a threaded end 132 that protrudes into the cham-

ber 128 of the isostatic press 110 when the end plug 114

is applied as shown in Figure 12.

When the surge arresting block 24 is to be

formed using the isostatic press 110, the end plug 114 is

put into place, and the chamber 128 is filled with the

material to be used in forming the surge arresting block

24. For example, if the surge arresting block 24 is to be a zinc oxide surge arresting block, the chamber 128 is

filled with a mixture of a metal oxide powder and a bond¬

ing agent such as polyvinyl alcohol, where the bonding

agent is about 1% by weight of the total mixture, al-

though more bonding agent could be used. Then, the end

plug 112 is put into place. Pressure greater than 5000

psi (such as 9200 psi) is applied to the isostatic press

110 through an inlet pipe 134 for a predetermined amount

of time.

Thereafter, the isostatic press 110 is opened

and the end plugs 112 and 114 are removed from the surge

arresting block 24. To this end, the stems 124 and 130

of the inserts 120 and 122 may be provided with the type

of ball latches that are used in socket wrenches in order

to facilitate removal of the end plugs 112 and 114 from

the inserts 120 and 122 which, to this point, are still

attached to the surge arresting block 24. The inserts

120 and 122 are then threaded out of the surge arresting

block 24 leaving the female threads 100 in each end of

the surge arresting block 24. The surge arresting block 24 may be provided

with the male threads 102 in much the same way. However,

instead of using the inserts 120 and 122, the recesses

116 and 118 are themselves threaded so that, when pres-

sure is applied to the isostatic press, some of the mate¬

rial in the chamber 128 is forced into the threaded re¬

cesses 116 and 118. After this pressure has been applied

for a predetermined amount of time, the isostatic press

110 is opened and the end plugs 112 and 114 are threaded

off of the surge arresting block 24 leaving tne male

threads 102 at each end of the surge arresting block 24.

The surge arresting block 24 may be provided

with the male threads 104 by suitably threading the bag

defining the chamber 128 which, after pressure is applied

to the isostatic press 110 through the inlet 134, would

leave impressions in the surge arresting block 24 to form

the male threads 104.

Certain modifications of the present invention

have been discussed above. Other modifications will

occur to those practicing in the art of the present

invention. For example, the first terminal 16 and the first end connector 20 are shown as being separate ele¬

ments. Instead, the first terminal 16 and the first end

connector 20 may be formed as a single, integrated, elec¬

trically conductive element.

Also, as described above, the surge arrester 10

is assembled in the following order. First, the arrester

housing 26 is applied to the stack of the surge arresting

block 24 which is stacked between the first and second

end connectors 20 and 22. Second, this arrangement is

then secured to the mounting bracket 30. Third, the

subassembly 74 is applied to the second end connector 22.

Instead, the surge arrester 10 may be assembled in any

desired order. For example, the arrester housing 26 may

first be applied to the stack of the surge arresting

block 24 and the first and second end connectors 20 and

22. Second, the subassembly 74 may be applied to the

second end connector 22. Third, the resulting arrange¬

ment may be then secured to the mounting bracket 30.

Additionally, the plastic cup 56 may be formed

of any type of electrically insulating material other

than plastic. Moreover, an electrically conductive spring,

such as a spring washer, may be inserted between the

second electrically conductive washer 50 and the internal

wall 52.

Furthermore, as described above, the first and

second metallized electrodes 60 and 62, if silver, are

sprayed or coated on the surge arresting block 24 and, if

aluminum, are arc sprayed on the surge arresting block

24. Instead, other application techniques may be used to

apply the first and second metallized electrodes 60 and

62 to the surge arresting block 24.

Accordingly, the description of the present

invention is to be construed as illustrative only and is

for the purpose of teaching those skilled in the art the

best mode of carrying out the invention. The details may

be varied substantially without departing from the spirit

of the invention, and the exclusive use of all modifica¬

tions which are within the scope of the appended claims

is reserved.

Claims

WHAT IS CLAIMED IS:

1. A surge arrester comprising:

an electrically insulating arrester housing;

and,

a surge arresting block housed within the

electrically insulating arrester housing, wherein the

surge arresting block is arranged to provide support for

the surge arrester without the use of a support member.

2. The surge arrester of claim 1 wherein the

surge arresting block is the only surge arresting block

housed within the electrically insulating arrester hous¬

ing.

3. The surge arrester of claim 2 wherein the

surge arresting block has a voltage rating of at least 9

KV.

4. The surge arrester of claim 1 further com-

prising an electrically insulating, non-supporting member

around the surge arresting block.

5. The surge arrester of claim 4 wherein the

surge arresting block is the only surge arresting block

housed within the electrically insulating arrester hous-

ing, and wherein the surge arresting block has a voltage

rating of at least 9 KV.

6. The surge arrester of claim 1 further com-

prising connectors adapted to connect the surge arresting

block between first and second electrical lines.

7. The surge arrester of claim 6 wherein the

surge arresting block is the only surge arresting block

housed within the electrically insulating arrester hous-

ing, and wherein the surge arresting block has a voltage

rating of at least 9 KV.

8. The surge arrester of claim 6 wherein the

connectors are bonded to the surge arresting block.

9. The surge arrester of claim 6 wherein the

connectors threadably engage threads of the surge arrest¬

ing block.

10. The surge arrester of claim 9 wherein the

surge arresting block is fabricated of a material, and

wherein the threads of the surge arresting block are

formed of the material .

11. The surge arrester of claim 9 wherein the

threads of the surge arresting block are metallized.

12. The surge arrester of claim 1 wherein the

surge arresting block is a first surge arresting block

fabricated of a material, wherein the surge arrester

further comprises a second surge arresting block fabri-

cated of the material, wherein the first and second surge

arresting blocks have threads formed of the material, and wherein the first and second surge arresting blocks

threadably engage one another to provide the support for

the surge arrester without the use of a support member.

13. The surge arrester of claim 12 wherein the

threads formed of the material are first threads of the

first and second surge arresting blocks, wherein the

first surge arresting block has second threads formed of

the material, wherein che second surge arresting block

has second threads formed of the material, wherein the

second threads of the first surge arresting block

threadably engage a first connector, wherein the second

threads of the second surge arresting block threadably

engage a second connector, wherein the first connector is

adapted to connect the first surge arresting block to a

first electrical line, and wherein the second connector

is adapted to connect the second surge arresting block to

a second electrical line.

14. The surge arrester of claim 1 further com-

prising: a first connector in electrical contact with a

first end of the surge arresting block;

a second connector in electrical contact with a

second end of the surge arresting block; and

a disconnector in electrical contact with the

second connector and arranged to disconnect the surge ar-

rester from an electrical line in the event of a fault in

the surge arresting block.

15. The surge arrester of claim 1 wherein the

surge arresting block has metallized first and second

ends .

16. The surge arrester of claim 1 wherein the

surge arresting block is a first surge arresting block

fabricated of a material, wherein the surge arrester

further comprises a second surge arresting block fabri-

cated of the material, wherein the first and second surge

arresting blocks have female threads formed of the mate-

rial, and wherein a threaded stud threadably engages the

female threads of the first and second surge arresting

blocks in order to provide the support for the surge

arrester without the use of a support member.

17. The surge arrester of claim 1 wherein the

surge arresting block is a first surge arresting block

fabricated of a material, wherein the surge arrester

further comprises a second surge arresting block fabri-

cated of the material, wherein the first and second surge

arresting blocks have male threads formed around an outer

perimeter of the first and second surge arresting blocks,

and wherein a threaded sleeve threadably engages the male

threads of the first and second surge arresting blocks in order to provide the support for the surge arrester with¬

out the use of a support member .

18. A surge arrester comprising a single surge

arresting block housed within an electrically insulating

arrester housing, wherein the single surge arresting

block is fabricated of a material, and wherein the single

surge arresting block has threads formed of the material .

19. The surge arrester of claim 18 wherein the

threads are male threads .

20. The surge arrester of claim 18 wherein the

threads are female threads .

21. The surge arrester of claim 18 wherein the

single surge arresting block has a voltage rating of at

least 9 KV.

22. The surge arrester of claim 18 wherein the

threads are metallized.

23. The surge arrester of claim 18 further

comprising an electrically insulating, non-supporting

member around the single surge arresting block.

24. The surge arrester of claim 18 further

comprising connectors adapted to connect the single surge

arresting block between first and second electrical line-

25. The surge arrester of claim 24 wherein the

connectors threadably engage the threads of the single

surge arresting block.

26. The surge arrester of claim 25 wherein the

threads are metallized.

27. The surge arrester of claim 18 further

comprising:

a first connector in electrical contact with a

first end of the surge arresting block; a second connector in electrical contact with a

second end of the surge arresting block; and

a disconnector in electrical contact with the

second connector and arranged to disconnect the surge ar-

rester from an electrical line in the event of a fault in

the surge arresting block.

28. The surge arrester of claim 18 wherein the

surge arresting block has metallized first and second

ends .

29. A surge arrester comprising a surge ar-

resting block housed within an electrically insulating

arrester housing, wherein the surge arresting block is

fabricated of a continuous material so that the surge

arresting block is of unitary construction, and wherein

the surge arresting block has a voltage rating of at

least 9 KV.

30. The surge arrester of claim 29 wherein the

surge arresting block has threads formed of the material,

and wherein the threads are male threads .

31. The surge arrester of claim 29 wherein the

surge arresting block has threads formed of the material,

and wherein the threads are female threads.

32. The surge arrester of claim 29 further

comprising an electrically insulating, non -supporting

collar around the surge arresting block.

33. The surge arrester of claim 29 further

comprising connectors adapted to connect the surge ar¬

resting block between first and second electrical lines.

34. The surge arrester of claim 33 further

comprising an electrically insulating support member

around the surge arresting block, wherein the electri-

cally insulating, non-supporting member is arranged to

hold the connectors to the surge arresting block.

35. The surge arrester of claim 33 wherein the

connectors are bonded to the surge arresting block.

36. The surge arrester of claim 33 wherein the

connectors threadably engage threads of the surge arrest¬

ing block.

37. The surge arrester of claim 36 wherein the

threads of the surge arresting block are formed of the

material .

38. The surge arrester of claim 37 wherein the

threads are metallized.

39. The surge arrester of claim 29 further

comprising:

a first connector in electrical contact with a

first end of the surge arresting block;

a second connector in electrical contact with a

second end of the surge arresting block; and

a disconnector in electrical contact with the

second connector and arranged to disconnect the surge ar-

rester from an electrical line in the event of a fault in

the surge arresting block.

40. The surge arrester of claim 29 wherein the

surge arresting block has metallized first and second

ends.

41. The surge arrester of claim 29 wherein the

surge arresting block is a first surge arresting block

fabricated of a material, wherein the surge arrester

further comprises a second surge arresting block fabri-

cated of the material, wherein the first and second surge

arresting blocks have female threads formed of the mate- rial, and wherein a threaded stud threadably engages the

female threads of the first and second surge arresting

blocks in order to provide the support for the surge

arrester without the use of a support member.

42. The surge arrester of claim 29 wherein the

surge arresting block is a first surge arresting block

fabricated of a material, wherein the surge arrester

further comprises a second surge arresting block fabri-

cated of the material, wherein the first and second surge

arresting blocks have male threads formed around an outer

perimeter of the first and second surge arresting blocks,

and wherein a threaded sleeve threadably engages the male

threads of the first and second surge arresting blocks in

order to provide the support for the surge arrester with¬

out the use of a support member.

43. A method of forming a surge arresting

block comprising the following steps: a) placing sufficient material in an isostatic

press to form a surge arresting block having a voltage

rating of at least 9 KV; and,

b) controlling the isostatic press with a

pressure/time profile arranged to bond the material to¬

gether in order to form the surge arresting block.

44. The method of claim 43 wherein step a)

comprises the step of placing sufficient metal oxide

material in the isostatic press to form a surge arresting

block having a voltage rating of at least 9 KV.

45. The method of claim 43 further comprising

the step of placing threads in the isostatic press prior

to step b) so that, when step b) is performed, threads

are formed in the surge arresting block.

46. The method of claim 43 further comprising

the step of placing male threaded members in the iso-

static press prior to step b) so that, when step b) is performed, female threads are formed in the surge arrest¬

ing block.

47. The method of claim 43 further comprising

the step of placing female threaded members in the iso-

static press prior to step b) so that, when step b) is

performed, male threads are formed in the surge arresting

block.

48. The method of claim 43 further comprising

the step of placing a threaded electrical connector in

the isostatic press prior to step b) so that, when step

b) is performed, the surge arresting block is formed with

the threaded electrical connector as a part thereof .

49. The method of claim 43 further comprising

the steps of:

firing the surge arresting block;

applying a collar to the surge arresting block;

applying metal electrodes to the surge arrest-

ing block; and, firing the surge arresting block.

50. The method of claim 49 wherein the step of

applying metal electrodes to the surge arresting block

comprises the step of applying silver electrodes to the

surge arresting block.

51. The method of claim 43 further comprising

the steps of :

firing the surge arresting block;

applying a collar to the surge arresting block;

firing the surge arresting block; and,

applying metal electrodes to the surge arrest¬

ing block.

52. The method of claim 51 wherein the step of

applying metal electrodes to the surge arresting block

comprises the step of applying aluminum electrodes to the

surge arresting block.

53. The method of claim 43 further comprising

the step of metallizing ends of the surge arresting

block.

AMENDED CLAIMS

[received by the International Bureau on 30 October 1998 (30.10.98) original claims 1-53 replaced by amended claims 1-46

(13 pages)]

1. A surge arrester comprising a surge arresting block, wherein the surge arresting block is fabricated of a material, and wherein the surge arresting block has threads formed of the material .

2. The surge arrester of claim 1 wherein the threads are male threads.

3. The surge arrester of claim 1 wherein the threads are female threads.

4. The surge arrester of claim 1 wherein the surge arresting block has a voltage rating of at least 9 KV.

5. The surge arrester of claim l wherein the threads are metallized.

6. The surge arrester of claim 1 further com- prising an electrically insulating, non-supporting member around the surge arresting block.

7. The surge arrester of claim 1 further com- prising a connector adapted to couple the surge arresting block to an electrical line, wherein the connector threadably engages the threads of the surge arresting block.

8. The surge arrester of claim 7 wherein the threads are metallized.

9. The surge arrester of claim 1 wherein the threads comprise first and second threads at corresponding ends of the surge arresting block, wherein the surge arrester further comprises first and second connectors adapted to couple the surge arresting block between first and second electrical lines, wherein the first connector threadably engages the first threads of the surge arresting block and is adapted to electrically couple the surge arresting block to the first electrical line, and wherein the second connector threadably engages the second threads of the surge arresting block and is adapted to electrically couple the surge arresting block to the second electrical line.

10. The surge arrester of claim 9 wherein the threads are metallized.

11. The surge arrester of claim 1 further com- prising: a first connector in electrical contact with a first end of the surge arresting block; a second connector in electrical contact with a second end of the surge arresting block; and a disconnector in electrical contact with the second connector and arranged to disconnect the surge ar- rester from an electrical line in the event of a fault in the surge arresting block.

12. The surge arrester of claim 11 wherein the surge arresting block has metallized first and second ends .

13. The surge arrester of claim 1 further comprising an electrically insulating arrester housing, wherein the electrically insulating arrester housing houses the surge arresting block and no other surge arresting block.

14. The surge arrester of claim 13 wherein the surge arresting block has a voltage rating of at least 9 KV.

15. The surge arrester of claim 13 further comprising a connector adapted to couple the surge arresting block to an electrical line, wherein the connector threadably engages the threads of the surge ar- resting block.

16. The surge arrester of claim 15 wherein the threads are metallized.

17. The surge arrester of claim 13 wherein the threads comprise first and second threads at corresponding ends of the surge arresting block, wherein the surge arrester further comprises first and second connectors adapted to couple the surge arresting block between first and second electrical lines, wherein the first connector threadably engages the first threads of the surge arresting block and is adapted to electrically couple the surge arresting block to the first electrical line, and wherein the second connector threadably engages the second threads of the surge arresting block and is adapted to electrically couple the surge arresting block to the second electrical line.

18. The surge arrester of claim 17 wherein the threads are metallized.

19. The surge arrester of claim 17 further comprising a disconnector in electrical contact with the second connector and arranged to disconnect the surge ar- rester from an electrical line in the event of a fault in the surge arresting block.

20. The surge arrester of claim 1 wherein the surge arresting block is a first surge arresting block, wherein the surge arrester further comprises a second surge arresting block fabricated of the material, wherein the second surge arresting block has threads formed of the material of the second surge arresting block, and wherein the threads of the first and second surge arresting blocks threadably engage in order to provide the support for the surge arrester without the use of a support member.

21. The surge arrester of claim 20 wherein the threads formed of the material of the first surge arresting block are first threads of the first surge ar- resting block, wherein the threads formed of the material of the second surge arresting block are first threads of the second surge arresting block, wherein the first surge arresting block has second threads formed of the material of the first surge arresting block, wherein the second surge arresting block has second threads formed of the material of the second surge arresting block, wherein the second threads of the first surge arresting block threadably engage a first connector, wherein the second threads of the second surge arresting block threadably engage a second connector, and wherein the first and second surge arresting blocks are electrically interconnected by way of the first threads of the first surge arresting block and the first threads of the second surge arresting block.

22. The surge arrester of claim 21 wherein the first threads of the first and second surge arresting blocks are female threads, and wherein a threaded stud threadably engages the female first threads of the first and second surge arresting blocks in order to provide the support for the surge arrester without the use of a support member.

23. The surge arrester of claim 21 wherein the first threads of the first and second surge arresting blocks are male threads formed around an outer perimeter of the first and second surge arresting blocks, and wherein a threaded sleeve threadably engages the male first threads of the first and second surge arresting blocks in order to provide the support for the surge arrester without the use of a support member.

24. The surge arrester of claim 21 wherein the first threads of the first surge arresting block are male threads, wherein the first threads of the second surge arresting block are female threads, and wherein the male and female threads of the first and second surge arrest- ing blocks threadably engage in order to provide the support for the surge arrester without the use of a support member.

25. The surge arrester of claim 20 wherein the threads of the first and second surge arresting blocks are female threads, and wherein a threaded stud threadably engages the female threads of the first and second surge arresting blocks in order to provide the support for the surge arrester without the use of a support member.

26. The surge arrester of claim 20 wherein the threads of the first and second surge arresting blocks are male threads formed around an outer perimeter of the first and second surge arresting blocks, and wherein a threaded sleeve threadably engages the male threads of the first and second surge arresting blocks in order to provide the support for the surge arrester without the use of a support member.

27. The surge arrester of claim 20 wherein the threads of the first surge arresting block are male threads, wherein the threads of the second surge arrest- ing block are female threads, and wherein the male threads of the first surge arresting block threadably engage the female threads of the second surge arresting block in order to provide the support for the surge arrester without the use of a support member.

28. The surge arrester of claim 1 further com- prising an electrically insulating collar around the surge arresting block.

29. The surge arrester of claim 28 further comprising first and second connectors adapted to couple the surge arresting block between corresponding first and second electrical lines.

30. The surge arrester of claim 29 wherein the electrically insulating collar is arranged to hold the first and second connectors to the surge arresting block.

31. The surge arrester of claim 29 wherein the first and second connectors are bonded to the surge arresting block.

32. The surge arrester of claim 29 wherein the first and second connectors threadably engage the threads of the surge arresting block.

33. The surge arrester of claim 28 further comprising a disconnector in electrical contact with the second connector and arranged to disconnect the surge ar- rester from an electrical line in the event of a fault in the surge arresting block.

34. The surge arrester of claim 28 wherein the surge arresting block is a first surge arresting block, wherein the surge arrester further comprises a second surge arresting block fabricated of the material, wherein the second surge arresting block has threads formed of the material, wherein the threads of the first and second surge arresting blocks are female threads, and wherein a threaded stud threadably engages the female threads of the first and second surge arresting blocks in order to provide the support for the surge arrester without the use of a support member.

35. The surge arrester of claim 28 wherein the surge arresting block is a first surge arresting block, wherein the surge arrester further comprises a second surge arresting block fabricated of the material, wherein the second surge arresting block has threads formed of the material, wherein the threads of the first and second surge arresting blocks are male threads formed around an outer perimeter of the first and second surge arresting blocks, and wherein a threaded sleeve threadably engages the male threads of the first and second surge arresting blocks in order to provide the support for the surge arrester without the use of a support member.

36. The surge arrester of claim 28 wherein the surge arresting block is a first surge arresting block, wherein the surge arrester further comprises a second surge arresting block fabricated of the material, wherein the second surge arresting block has threads formed of the material, wherein the threads of the first surge arresting block are male threads, wherein the threads of the second surge arresting blocks are female threads, and wherein the male threads of the first surge arresting block threadably engages the female threads of the second surge arresting block in order to provide the support for the surge arrester without the use of a support member.

37. A method of forming the surge arrester o claim 1 comprising the following steps: a) placing material in an isostatic press to form the surge arresting block; and, b) controlling the isostatic press with a pressure/time profile arranged to bond the material together in order to form the surge arresting block.

38. The method of claim 37 wherein step a) comprises the step of placing metal oxide material in the isostatic press to form the surge arresting block.

39. The method of claim 37 further comprising the step of placing threads in the isostatic press prior to step b) so that, when step b) is performed, threads are formed in the surge arresting block.

40. The method of claim 37 further comprising the step of placing a male threaded member in the isostatic press prior to step b) so that, when step b) is performed, female threads are formed in the surge arresting block.

41. The method of claim 37 further comprising the step of placing a female threaded member in the isostatic press prior to step b) so that, when step b) is performed, male threads are formed in the surge arresting block .

42. The method of claim 37 further comprising the step of placing an electrical connector in the isostatic press prior to step b) so that, when step b) is performed, the surge arresting block is formed with the electrical connector as a part thereof .

43. The method of claim 37 further comprising the steps of: firing the surge arresting block; applying a collar to the surge arresting block; applying metal electrodes to the surge arresting block; and, firing the surge arresting block.

44. The method of claim 43 wherein the step of applying metal electrodes to the surge arresting block comprises the step of applying silver electrodes to the surge arresting block.

45. The method of claim 37 further comprising the steps of: firing the surge arresting block; applying a collar to the surge arresting block; firing the surge arresting block; and, applying metal electrodes to the surge arresting block.

46. The method of claim 45 wherein the step of applying metal electrodes to the surge arresting block comprises the step of applying aluminum electrodes to the surge arresting block.